EP3671073A1

EP3671073A1 - Electric expansion valve

Info

Publication number: EP3671073A1
Application number: EP18214593.8A
Authority: EP
Inventors: Sigurd Larsen; Kurt Harck; Søren Sottrup KRISTENSEN; Birthe Nissen REESE; Charlotte Vibeke Pingel VAGNSHOLDT
Original assignee: Danfoss AS
Current assignee: Danfoss AS
Priority date: 2018-12-20
Filing date: 2018-12-20
Publication date: 2020-06-24
Also published as: US20220042729A1; CN113039399B; CN113039399A; WO2020127062A1; US20240318743A1; US12072039B2

Abstract

An electric expansion valve (1) is described comprising a valve housing (12), a valve seat (2), a valve element (3) cooperating with the valve seat (2), a drive driving the valve element (3) and comprising a rotary motor (4) having an axis (17) of rotation, wherein the valve element (3) is connected to a motor (4).

Such expansion valve should ensure a long lifetime with low production costs.

To this end the valve element (3) is connected to the motor (4) having a possibility of a radiant displacement between the rotor (6) and the valve element (3) with respect to the axis (17) of rotation.

Description

The present invention relates to an electric expansion valve comprising a valve housing, a valve seat, a valve element cooperating with the valve seat, a drive driving the valve element and comprising a rotary motor having an axis of rotation, wherein the valve element is connected to the motor.
Such a valve can be used, for example, to control a flow of a refrigerant through a cooling or refrigeration system. When the rotary motor is operated, the valve element is moved towards or away from the valve seat. In order to interrupt the flow of the refrigerant through the expansion valve it is necessary, that a valve element fully contacts the valve seat, i.e. there must not be a gap between the valve element and the valve seat. This requires a rather exact guidance of the valve element with respect to the valve seat.
The valve element has to be connected to the motor and the motor has to be positioned with respect to the housing. In order to achieve the above-mentioned condition, it is necessary to position the motor with a very high accuracy with respect to the valve housing. This makes manufacturing of such a valve expensive. If the motor is positioned with less accuracy, the production costs can be lowered. However, the consequence of this is that the expansion valve has reduced lifetime, since there is an important wear of the moving parts of the valve element.
The object underlying the invention is to ensure a long lifetime with low production costs.
This object is solved with an electric expansion valve as described in the outset in that the valve element is connected to the motor having a possibility of a radial displacement between the rotor and the valve element with respect to the axis of rotation.
Such a construction does not require a very high accuracy when positioning the motor with respect to the housing. A small offset between the axis of rotation and the moving axis of the valve element is allowed, since the connection between the valve element and the motor allows a radial movement or displacement of the rotor relative to the valve element and vice versa.
In an embodiment of the invention the rotary motor comprises a rotor which is fixed in axial direction with respect to the housing, wherein a transmission is arranged between the rotor and the valve element translating a rotary movement of the rotor into a translational movement of the valve element. When the rotor of the motor is fixed in axial direction, the magnetic condition does not change in dependence of the axial position of the valve element. The torque, which can be produced by the cooperation of a stator and the rotor of the electric motor, can be kept constant over the whole working stroke of the valve element.
In an embodiment of the invention the rotor is supported by a bearing arranged on a side of the rotor opposite the valve element. The bearing does not conflict with other parts of the valve, in particular with the valve element and the transmission.
In an embodiment of the invention the transmission comprises a lead screw and a lead nut. When, for example, the rotor is connected to the lead screw and the lead nut is secured against rotation, a rotation of the rotor and a corresponding rotation of the lead screw leads to a translational movement of the lead nut.
In an embodiment of the invention the valve seat is part of the housing. Accordingly, it is not necessary to mount a separate part into the housing forming the valve seat. The length of the guide section should be larger than the internal diameter of the guide section.
In an embodiment of the invention the valve seat is rounded. In other words, the edge of a bore forming the valve seat has been machined to form a rounded edge. Such a construction facilitates a tight closure of the valve.
In an embodiment of the invention the housing comprises a guide section guiding the valve element. The guiding section and the valve seat are aligned with respect to each other. The valve seat and the guide section can be machined in a single production step making it easy to align the guide section and the valve seat. The internal diameter of the guide section is only slightly larger than the diameter of the valve element, for example by 0,1 mm.
In an embodiment of the invention the valve element and the housing are of different materials at least in the guide section. One possible pairing of materials is brass for the valve element and steel for the housing. These two materials can slide against each other without or with little wear as long as the material can slide with respect to each other with low friction. The different materials can include different metal alloys including different steel alloys.
In an embodiment of the invention the valve element is connected to the motor by means of a spring element. The spring element can guarantee a defined position of the valve element in axial direction while allowing a radial displacement between axis of rotation and a valve element. A small axial displacement may be possible, however such an axial displacement in less then factor 10 of a possible radial displacement.
In an embodiment of the invention the valve element is connected to the motor by means of the lead nut. The connection between the valve element and the lead nut allows for the radial displacement between the lead nut and the valve element.
In an embodiment of the invention the spring element comprises a frame enclosing an area which is larger than the cross section of the spring element, wherein the frame comprises at least a finger protruding into an elongated recess at the valve element. The frame forms at least partly a border limiting relative movement between the valve element and the driven part of the motor. It simplifies the mounting of the valve element. The spring element can be mounted on the lead nut before the spring element is connected to the valve element.
In an embodiment of the invention the frame comprises a section bent away from the rotor. The bent section forms a stop limiting a movement of the spring element with respect to the valve element.
In an embodiment of the invention the spring element is U-shaped in a side view, wherein a base of the U forms a stop. The base of the U is opposite to the section bent away from the rotor. The base and the bent section form two stops. They are preferably arranged in a line parallel to the direction of the finger, wherein it is preferred that a pair of opposing fingers is used.
In an embodiment of the invention the spring element fixes a valve element to an element of the transmission which is fixed against rotation. This element can be, for example, the lead nut. This simplifies the assembly of the valve.
A preferred embodiment of the invention will now be described in more detail with reference to the drawing, wherein:

Fig. 1: shows a sectional view through an expansion valve,
Fig. 2: shows a valve element of the expansion valve and a transmission,
Fig. 3: shows a spring element connecting the valve element and the transmission,
Fig. 4: shows a side view of the valve element connecting to a lead screw,
Fig. 5: shows a front view of the valve element connected to the lead screw and
Fig. 6: shows a detail A of fig. 5.

Fig. 1 shows an expansion valve 1 in a sectional view. The expansion valve 1 comprises a valve seat 2 and a valve element 3. The valve element 3 can be moved towards and away from the valve seat 2. To this end the valve element 3 is driven by drive means comprising a rotary motor 4. The motor 4 comprises a stator 5 and a rotor 6. The rotor 6 is supported by a bearing 29 located on a side of the rotor 6 opposite the valve element 3. The motor 4 can be in form of a stepper motor.
The rotor 6 is operatively connected to a shaft 7. This can be achieved in that the rotor 6 is mounted rotatable on shaft 7 and drives the shaft 7 indirectly by means of a follower arrangement comprising a pin 8 which is connected to the rotor 6 and protrudes into a stop member 9 which is connected to the shaft 7. However, other connections are possible.
The shaft 7 comprises an outer thread forming a lead screw 10. The lead screw 10 is threadedly connected to a lead nut 11. The lead nut 11 is rotatably fixed with respect to a housing 12. When the shaft 7 rotates in one direction, the lead nut 11 is translated in one direction and when the shaft 7 rotates in the opposite direction the lead nut 11 is translated into the other direction.
The valve element 3 is connected to the lead nut 11 so that a movement of the lead nut 11 is directly transferred to the valve element 3.
The housing 12 comprises a guiding section 13 guiding the valve element 3. The valve element 3 and the housing 12 are made of different materials, in particular different metal materials. The housing 12 can be, for example, made of steel and the valve element 3 can be, for example, of brass. The pairing of brass and steel allows a sliding of the valve element 3 in the guiding section 13 with low friction and accordingly of low wear. Other pairings of materials can be used, for example, different metal alloys including different steel alloys.
The guiding section 17 of the valve element is preferably larger than the diameter of the guiding section 13. When the diameter of the valve element 3 is d1 and the diameter of the guiding section 13 is d2, then the following relation is fulfilled: d1>d2>d1+0,1 mm. The connection between the valve element 3 and the rotor 6 of the motor 4 allows a displacement of, for example 0,2 mm. Together this allows for a radial displacement of the valve element relative to the rotor of +-0,2 mm.
The valve seat 2 is part of the housing 12. It is aligned with the guiding section 13 which can easily be achieved by producing the valve seat 2 and the guiding section 13 in the same production step, for example with the same drill.
The valve seat 2 is rounded. It forms a round edge of a bore 14 into which a protrusion 15 of the valve element can enter when the valve 1 is closed.
The valve element 3 is connected to the lead nut 11 by means of a spring element 16 fixing the valve element 3 to the lead nut 11 in axial direction, but allowing a radial displacement of the shaft 7 and the lead nut 11 in radial direction relative to the valve element 3, wherein the radial direction refers to an axis 17 of rotation of the shaft 7.
The assembly of valve element 3, shaft 7, lead screw 10, lead nut 11 and spring element 16 is shown in fig. 2. The lead screw 10 is threaded into the lead nut 11. The lead nut 11 is of rectangular cross section to secure it against a rotation relative to the housing 12.
The spring element 16 is shown in more details in fig. 3. The spring element 16 comprises a frame 18 around an open area 19. Area 19 is larger than the cross section of the valve element 3. Frame 18 comprises two fingers 20, 21 protruding into the open area 19. When the spring element 16 is mounted to the valve element 3 the fingers 20, 21 protrude into an elongated recess 22 in the valve element 3. A simple form of the recess 22 is a groove running in circumferential direction so that an angular orientation of the valve element 3 with respect to the spring element 16 is of no importance when assembling these parts.
In a side view shown in fig. 4 the spring element 16 is of U-form having a base 23 which rests against the lead nut 11 or forms at least a stop against which the lead nut 11 comes to rest.
Furthermore, the spring element 16 comprises a pair of spring fingers 24, 25 which are connected to the frame 18 by means of the base 23. The spring fingers 24, 25 together with the frame 18 and the fingers 20, 21 produce a force acting on the valve element 3 in a direction towards the motor 4, i.e. the spring element 16 pulls the valve element 3 against the lead nut 11 in axial direction (related to the axis 17 of rotation).
The frame 18 comprises an angled section 26 which is bent away from the rotor 6 and thus away from the lead nut 11. An inner border 27 of the angled section 26 forms a stop limiting a movement of the spring element 16 with respect to the valve element 3 in a direction perpendicular to the angled section.
As can be seen in fig. 6 there is no or only a limited axial play between the valve element 3 and the lead nut 11. However, there is a radial play allowing a radial displacement 28 between the valve element 3 and the lead nut 11.
In other words, even when the axis 17 of rotation is not exactly aligned with the centre of the guiding section 13 there are basically no lateral forces on the valve element 3 pressing the valve element 3 into the guiding surface of the guiding section 13. The spring element 16 allows a small radial displacement between the lead nut 11 and the valve element 3.
The use of a transmission comprising a lead screw 10 and a lead nut 11 allows to keep the rotor 6 of the motor 4 stationary within the stator 5, i.e. independently of the position of the valve element 3 the magnetic forces acting between the stator 5 and the rotor 6 are always the same. In other words, the rotor 6 is only rotating and not translating.
The only moving parts touching each other are the valve element 3 and the housing 12 and this contact can be limited to the guiding section 13.

Claims

Electric expansion valve (1) comprising a valve housing (12), a valve seat (2), a valve element (3) cooperating with the valve seat (2), a drive driving the valve element (3) and comprising a rotary motor (4) having an axis (17) of rotation, wherein the valve element (3) is connected to the motor (4), characterized in that the valve element (3) is connected to the motor (4) having a possibility of a radial displacement between the rotor (6) and the valve element (3) with respect to the axis (17) of rotation.
Expansion valve according to claim 1, characterized in that the rotary motor (4) comprises a rotor (6) which is fixed in axial direction with respect to the housing (12), wherein a transmission (10, 11) is arranged between the rotor (6) and the valve element (3) translating a rotary movement of the rotor (6) into a translational movement of the valve element (3).
Expansion valve according to claim 2, characterized in that the rotor (6) is supported by a bearing (29) arranged on a side of the rotor (6) opposite the valve element (3).
Expansion valve according to claim 2 or 3, characterized in that the transmission (10, 11) comprises a lead screw (10) and a lead nut (11).
Expansion valve according to any of claims 1 to 4, characterized in that the valve seat (2) is part of the housing (12).
Expansion valve according to any of claims 1 to 5, characterized in that the valve seat (2) is rounded.
Expansion valve according to any of claims 1 to 6, characterized in that the housing (12) comprises a guide section (13) guiding the valve element (3).
Expansion valve according to claim 7, characterized in that the valve element (3) and the housing (12) are of different materials at least in the guide section (13).
Expansion valve according to any of claims 1 to 8, characterized in that the valve element (3) is connected to the motor (4) by means of a spring element (16).
Expansion valve according to any of claims 1 to 8, characterized in that the valve element (3) is connected to the motor (4) by means of the lead nut (11).
Expansion valve according to claim 9, characterized in that the spring element (16) comprises a frame (18) enclosing an area (19) which is larger than the cross section of the valve element (3), wherein the frame (18) comprises at least a finger (20, 21) protruding into an elongated recess (22) at the valve element (3).
Expansion valve according to claim 11, characterized in that the frame (18) comprises a section (26) bent away from the rotor (6).
Expansion valve according to any of claims 9 to 12, characterized in that the spring element (16) is U-shaped in a side view, wherein a base (23) of the U forms a stop.
Expansion valve according to any of claims 9 to 13, characterized in that the spring element (16) fixes the valve element (3) to an element (11) of the transmission (10, 11) which is fixed against rotation.